Department of Animal Sciences, University of Illinois, Urbana 61801, USA.
J Anim Sci. 2012 Feb;90(2):657-68. doi: 10.2527/jas.2011-4310. Epub 2011 Oct 7.
This study explored the hypothesis that mannan oligosaccharide (MOS) acts to reduce systemic inflammation in pigs by evaluating cytokine production of alveolar macrophages (AM) and serum cytokine concentrations. A total of 160 pigs were fed diets containing 0.2 or 0.4% MOS for 2 or 4 wk postweaning compared with control diets without MOS. Dietary MOS did not affect the serum concentration of tumor necrosis factor (TNF)-α and tended (P = 0.081) to increase that of IL-10. These cytokine concentrations also changed over time (P < 0.001). After 2-wk feeding of the control or MOS diets, AM were collected and stimulated ex vivo with lipopolysaccharide (LPS) or polyinosinic:polycytidylic acid (PLIC) as infection models. The LPS-stimulated AM from MOS-fed pigs (n = 12) secreted less TNF-α (P < 0.001) and more IL-10 (P = 0.026) than those from control-fed pigs (n = 6). However, dietary MOS had less effect on ex vivo TNF-α and IL-10 production by PLIC-stimulated AM (P = 0.091 and P > 0.10, respectively. Further, effects of MOS were examined in 4 in vitro experiments. In Exp. 1 (n = 4 pigs), MOS and mannan-rich fraction (MRF), when added to AM cultures, were able to increase TNF-α production. This direct effect of MOS was not due to endotoxin contamination as verified in Exp. 2 (n = 6 pigs) using polymyxin B, an inhibitor of LPS activation of toll-like receptor 4. Polymyxin B inhibited production of TNF-α by AM after treatment with LPS (P < 0.001), but not after treatment with MOS in the absence of LPS (P > 0.70). In Exp. 3 (n = 6 pigs), when MOS was directly applied in vitro, the pattern of cytokine production by LPS-activated AM was similar to that observed ex vivo, as MOS suppressed LPS-induced TNF-α (P < 0.001) and enhanced LPS-induced IL-10 (P = 0.028). In Exp. 4 (n = 6 pigs), when MRF replaced MOS, AM-produced TNF-α induced by LPS or PLIC was suppressed by MRF (P = 0.015 or P < 0.001, respectively). These data establish that MOS and MRF suppress LPS-induced TNF-α secretions by AM. Generally, the study suggests that MOS may be a potent immunomodulator because it directly activates AM to secrete TNF-α and alters the cytokine responses of bacterial endotoxin-induced AM in both ex vivo and in vitro systems. In particular, feeding MOS to pigs for 2 wk reduces TNF-α and increases IL-10 concentrations after ex vivo treatment of AM with LPS. These immunomodulatory properties of MOS may have important implications for both host defense and avoidance of harmful overstimulation of the immune system.
本研究通过评估肺泡巨噬细胞(AM)的细胞因子产生和血清细胞因子浓度,探究甘露寡糖(MOS)通过减少全身炎症来发挥作用的假说。在断奶后 2 或 4 周,160 头猪分别喂食含有 0.2%或 0.4% MOS 的日粮或不含 MOS 的对照日粮。日粮 MOS 不影响肿瘤坏死因子(TNF)-α的血清浓度,且有增加 IL-10 浓度的趋势(P = 0.081)。这些细胞因子浓度也随时间变化(P < 0.001)。在用脂多糖(LPS)或聚肌苷酸:聚胞苷酸(PLIC)作为感染模型对控制或 MOS 喂养的猪的 AM 进行离体刺激后,收集 AM。与对照喂养的猪(n = 6)相比,MOS 喂养的猪(n = 12)的 LPS 刺激的 AM 分泌更少的 TNF-α(P < 0.001)和更多的 IL-10(P = 0.026)。然而,日粮 MOS 对 PIC 刺激的 AM 的体外 TNF-α和 IL-10 产生的影响较小(P = 0.091 和 P > 0.10,分别)。此外,在 4 项体外实验中检验了 MOS 的作用。在实验 1(n = 4 头猪)中,当 MOS 和甘露聚糖丰富部分(MRF)添加到 AM 培养物中时,能够增加 TNF-α的产生。这种 MOS 的直接作用不是由于内毒素污染,因为在实验 2(n = 6 头猪)中使用多粘菌素 B(一种抑制 LPS 激活 Toll 样受体 4 的抑制剂)进行了验证。多粘菌素 B 抑制了 LPS 处理后 AM 中 TNF-α的产生(P < 0.001),但 LPS 处理后未添加 MOS 时(P > 0.70)则没有抑制。在实验 3(n = 6 头猪)中,当 MOS 直接在体外应用时,LPS 激活的 AM 产生的细胞因子模式与体内观察到的相似,因为 MOS 抑制了 LPS 诱导的 TNF-α(P < 0.001)并增强了 LPS 诱导的 IL-10(P = 0.028)。在实验 4(n = 6 头猪)中,当 MRF 替代 MOS 时,LPS 或 PLIC 诱导的 LPS 诱导的 AM 产生的 TNF-α被 MRF 抑制(P = 0.015 或 P < 0.001,分别)。这些数据表明 MOS 和 MRF 抑制 LPS 诱导的 AM 产生的 TNF-α。一般来说,该研究表明 MOS 可能是一种有效的免疫调节剂,因为它直接激活 AM 分泌 TNF-α,并改变细菌内毒素诱导的 AM 在体内和体外系统中的细胞因子反应。特别是,在断奶后 2 周内用 MOS 喂养猪,可减少 LPS 处理 AM 后 TNF-α和增加 IL-10 浓度。MOS 的这些免疫调节特性可能对宿主防御和避免免疫系统的有害过度刺激都具有重要意义。
